DE3605759C2 - Color television receiver with a television circuit for converting a time-division multiplex signal into simultaneous signals and suitable integrated circuit arrangement - Google Patents

Description

The invention relates to a color television receiver with a television circuit for converting a Time division multiplexed signal into simultaneous signals, this Time division multiplex signal an interrupted sequence of a first Has information related to luminance occurring in the first time periods, the first information by another sequence of second and third information in terms of color type, appearing in second or third ten time periods, are separated and the simultaneous Signals the first information, the second or third Information as well as repeated third or second Information correspond, with the possibly repeated second and third information have expanded over time, whereby these in the same simultaneous signals during same first and fourth time periods occur as that first information, the time periods television horizon tal sampling times correspond to what the television circuit between a circuit input and output with signal sampling expansion and repetition circuits for the second and third information related to the color type forms, the circuits with shift registers with different write or read speeds under control of clock pulses with different Clock pulse frequencies are formed, and to one of them suitable integrated circuit arrangement.

Such a color television receiver is e.g. B. usable in a color television system that is in a public report "Experimental and Development Report 118/82" the English "Independent Broadcasting Authority", (I.B.A.), entitled: "MAC: A Television System for High-Quality Satellite Broadcasting ". In the report for a so-called MAG (Multiplexed Analogue Component) image coding given several modifications.  

The same applies to all modifications as from an overview board on page 9 of the report shows that the luminance and the color type information each experience time compression, where the color information is twice larger is. From the color type information, the two components each Horizontal period alternately occurs one of the two time-compressed in the time-division multiplexed signal on. In this signal, that is added to each horizontal period ordered luminance information available in a time-compressed manner. The factors for the time compression are in the report 2/3 and 3/4 called, with time for the color information compression factors equal 1/3 and 3/8 follow. The picture information per horizontal period in the zietmultiplexko dated signal is sequential from the time compression assigned luminance information and one of the two time-compressed chromaticity information poses. In the receiver is the one on the transmission channel, d. H. the satellite link, received signal the time-division-multiplexed signal is removed and the be written circuit arrangement supplied with the help of synchronous and identification information a time expansion for gives the luminance and color type information and thereby the expanded chromaticity information about the following horizon period.

The modifications described can continue of a system in which the luminance information tion is not or hardly compressed, so that only the Color type information requires signal expansion.

The repetition of the color type information can be found in the receiver in a known manner by using a ver delay arrangement with a horizontal period delay be realized. This delay arrangement lies behind the expansion circuit, which during the one Hori Central period immediately and during the following hori zontalperiod over the delay arrangement the color type provides information. The requirements are that the delay arrangement the signal by exactly one Horizontal period delayed and still on amplitudes,  Frequencies and phases have no influence. The fulfillment These requirements lead to the use of an expensive, exact delay arrangement, with aging effects have no influence.

The object of the invention is now a color television receiver with a circuit arrangement of the described to create the same type, with the color type information again no elaborate processing of the simultaneous signals order of delay is necessary. An inventive Color television receiver is characterized in that in the signal sensing, expansion and repeat scarf device the input of the television circuit with a signal input of at least one input slide register from the Type row on, parallel-out coupled and the subject fende output of the television circuit with the expanded, possibly repeated second or third information in relation on the type of color with the relevant signal outputs first and second output shift registers of the type parallel-in, row-out is coupled, being parallel outputs of the input shift register via an on / off circuit with parallel inputs of the first and second Output shift registers are coupled, the input Switch-off circuit is switched on periodically before the first and fourth time periods occur while television Horizontal blanking times, and during the first or fourth time periods, the television horizontal scanning time last correspond, is switched off, alternating assign the first and second output shift registers each relevant horizontal scanning period, the second or third information and the repeated second or third Provides information at the relevant circuit output.

Apart from the favorable fact that at Get the bitmap repetition no delay arrangement needs to be used gives the same Signal handling for the direct and repeated color type signal an optimal equality of the two successive the output signals.

A simple embodiment of an invention  according to the color television receiver has the license plate, that the signal sampling, expansion and repetition circuit with a single input shift register a number of register levels that more or less the double the number of register stages of the output shift register corresponds, is formed, the parallel outputs of the input shift register alternately one after the other with the parallel inputs of the first and second off gear shift registers are coupled.

From this choice of an input shift register with twice the number of register levels it follows that the Clock pulse frequency when writing to the input register must be twice as large as in the known case simple input / output shift registers of the type series on, row-out, which acts as a signal expansion circuit is.

An embodiment in which not one is twice larger write clock pulse frequency is necessary the indicator that the signal sampling, expansion and repetition circuit with a first and a second input shift register, each with a number of registers levels that are more or less the number of register levels the output shift register corresponds to, is formed, the parallel outputs of the first and second inputs shift register with the parallel inputs of the first or second output shift registers are coupled.

This can be a further simple embodiment are characterized in that the clock pulse frequency in the sampling circuit, the output of which is switched circle with the relevant signal input of the first and second input shift register is coupled twice is greater than the clock pulse frequency at this input shift registers and the switching circuit.

Undesired to achieve that again got output signal exactly one horizontal period later occurs as the immediately preceding output signal, one embodiment is characterized in that the Read at the first and second output shift registers  out of phase. Because when you enroll in one Input shift register or in the two input shift register is the information in match the register stages by one write clock pulse period pushed.

To realize that with the help of simple Input shift register or the two input shift registers register the two color type information are processed one embodiment has the characteristic that the signal sampling, expansion and repetition circuit with four output shift registers which is called twice the first and second Output shift register with a first or second Output of the television circuit are coupled, the On / off circuits that one or the other pair first and second output shift registers are assigned, alternately during the first and second horizontal off duty cycles are effective.

An integrated circuit arrangement according to the Invention for use in a color television receiver is suitable, the indicator shows that in a Circuit substrate of a first semiconductor type at least three parallel channels of a different semiconductor type are present, with an inner channel from an adjacent one Outer channel through interrupted areas of the first half conductor type is separated, being isolated from the substrate above the channels that slide the input or output are assigned to separate electrode systems are, whereby over the mentioned areas in the Substrate and isolated from it, an electrode strip in front is present, this stripe and the areas the On / off circuit are assigned.

Another embodiment with a simple Input shift register is characterized in that in the first semiconductor type circuit substrate three parallel channels of the other semiconductor type are available are, the inner channel through broken areas of the first semiconductor type from the two outer channels  is separated, these interruptions by half Area length to one and the other outer channel ver are pushed, the outer channels on one in the Substrate closed end of the inner channel together meet, isolated from the substrate three separate Electrode systems over the inner channel and the two outer channels that the input shift register or are assigned to the two output shift registers are, with on both sides of the inner channel over the named areas in the substrate and isolated therefrom two electrode strips together with the areas are assigned to the on / off circuit.

Another embodiment, the two Provide color type information immediately and repeatedly can have the characteristic that in the circuit substrate of the first semiconductor type five parallel channels of the other semiconductor type are present, the inner Channel through interrupted areas of the first semiconductor type is separated from the two adjacent channels, whereby the interruptions are opposite each other, being a he called neighboring channel through interrupted areas of the first semiconductor type separated from an outer channel is, the breaks between the outer and the adjacent channel with half the number of interruptions between the inner channel and the adjacent channel are and with an outer channel and the adjacent channel meet at one end, being isolated from the sub strat five separate electrode systems over the inner one Channel and the two adjacent channels and two outer channels len, the input shift register or the four off gear shift registers are assigned, are available, being on both sides of the adjacent channels over the above Areas in the substrate and two electrically isolated therefrom the stripes are present, along with the areas are assigned to one of the on / off circuits.

An integrated embodiment of the circuit arrangement in which the structure of reading at the first and second output shift registers in phase opposition  is carried out, the marking shows that the together hitting channels at this point a last output have shift register level, the number of electrodes one last stage half of the other last stage.

An embodiment of the invention is in the drawing is shown and will be closer in the following wrote. It shows

Fig. 1 is a block schematic diagram of a circuit arrangement which forms a part of a color television receiver according to the invention,

Fig. 2 shows an overview of a possible exporting approximately form an integrated circuit arrangement with eini gen in Fig. 1 given elements,

Fig. 3 is a block schematic representation of another embodiment as in Fig. 1,

Fig. 4 is a Registered possible embodiment of an integrated circuit,

FIG. 5 shows a block diagram of a further embodiment differently than in FIG. 1.

In Fig. 1, A indicates an input shift register of the row-in, parallel-out type. The signal input of shift register A is coupled to a circuit input to which a time-division multiplex signal Y / U / V / specified is supplied. The input with the Y / U / V / signal is present in a color television receiver suitable for use in a color television system which is operative with the transmission or storage of the time-division multiplexed signal Y / U / V /. Y represents the information relating to the luminance of the and U and V are two pieces of information relating to the color type. It is assumed that the luminance information Y occurs as a first piece of information in an interrupted sequence, in first time periods T1, as indicated by YT1 in FIG. 1. The first information Y is separated by another sequence of second (U) and third (V) information related to the type of color, occurring in second (T2) and third (T3) periods, respectively, which is shown in FIG. 1 by UT2 and VT3 is given. The sequence in the time-division multiplex signal Y / U / V / can be arbitrary. One example is a cycle U, Y, V, Y over two horizontal periods. The luminance information Y is assigned to two successive television lines. The color type information U and V then belong as color difference signals both to one of these two television lines or one belongs to one line and the other to the other line. Regardless of this, it is necessary in the receiver to repeat the chromaticity information U and V once. The color type information U and V occur time-compressed in the time-division multiplex signal Y / U / V. It holds true for the luminance information Y that this may not occur in a compressed manner. In the cited article television systems are described in which the luminance information Y always occurs time-compressed in the time-division multiplex signal Y / U / V. In the Dutch patent application No. 8 301 013 (PHN 10.628) a television system is described in which the luminance information Y (almost not time-compressed in the time multiplex signal Y / U / V occurs, which also contains the compressed color type information U and V) The cycle is U, V, Y. Here too, information must be repeated for the color type information U and V. Regardless of the specific embodiment of the color television receiver, there is always the need for color type information repetition. The color television receiver can be used as a receiver Playback device with a display screen or as a receiver-transmitter The receiver-transmitter can form part of, for example, a common antenna system as a transcoding arrangement.

In Fig. 1 at the circuit input with the signal Y / U / V it is indicated that the luminance information Y is processed elsewhere in the color television receiver. The type of processing is left open because it is irrelevant to the invention. What is important is that ultimately three simultaneous signals are formed which correspond to the first information relating to the luminance and the second and third information relating to the color type and the repeated third and second information relating to the color type. The possibly repeated second and third information in relation to the type of color should be expanded in such a way that it occurs in (the first or fourth) periods in which the first information relating to the luminance also occurs or in the same television Horizontal scan times. In the case of the first or fourth time, the luminance information Y is not compressed or compressed in the time-division multiplex signal Y / U / V. In Fig. 1, the simultaneously made second, direct and repeated chromaticity information are given by U, U 'in a circuit output. Another possibility, indicated by dashed lines, is the delivery of the simultaneously made third direct and repeated color type information V, V '. The delivery of U, U 'or V, V' depends on the time periods T2 or T3 that the input shift register A is written. According to Fig. 1, the registration is carried out under control of clock pulses with a frequency FGP0, as indicated at a clock pulse input of the register A. The clock pulses with the clock pulse frequency FCP0 come from a clock pulse source, not shown, which can deliver further clock pulses with other frequencies. The occurrence of the clock pulses with the frequency FGP0 during the periods T2 or T3 determines whether ultimately the information U, U 'or V, V' occurs at the circuit output.

To explain the operation of the circuit according to the invention according to Fig. 1, the between the input with the time-division multiplex signal Y / U / V and the output with the signal U, U 'or V, V' with a Signalabtast-, -expan sions- and - repeat circuit is formed, the following applies. The input shift register A is shown with a number of (2m + 1) register stages A ₀ , A ₁ , A ₂ , A ₃ , A ₄ A _2m-1 , A _2m . The first stage A ₀ coupled to the input with the signal Y / U / V acts as a sampling circuit, the clock pulses with the frequency FCP0 acting as sampling clock signals. The following register stages are provided with parallel outputs, which alternate one after the other (A ₁ , A ₃ ... A _2m-1 ; A ₂ , A _{4 ...} A _2m ) via a first or second on / off circuit B1 or B2 are coupled to parallel inputs of a first or second output shift register C1 or C2. The register C1 or BC2 is with register levels C1 ₁ , C1 ₂ . . . C1 _m or C2 ₁ , C2 ₂ . . . C2 _m shown. It turns out that the number of (2m + 1) register stages of the input shift register A corresponds more or less to twice the number of m register stages of the output shift registers C1 and C2. The output shift registers C1 and C2 are of the parallel-on, row-out type, registers C1 and C2 are written from register A via the relevant on / off switching circuits B1 and B2, during a television horizontal blanking period THB , which follows the second or third time period UT2 or VT3, in which information is written into register A: FIG. 1 shows the duration THB for a circuit input for the common on / off circuit (B1, B2). After the duration THB, the circuit (B1, B2) is switched off and the output shift registers C1 and C2 can alternately be controlled for reading during television horizontal scanning periods THS. In Fig. 1 it is shown that a clock pulse input of the register C1 or C2 is coupled to a relevant output of a switching circuit denoted by D. The switching circuit D has a switching output in which a first horizontal scanning period is specified by THS1. In another switching output, a second, subsequent horizontal scanning period is specified by THS2, this output being coupled to the clock pulse input of register C2 via a phase reversing circuit (E) denoted by E. The switching circuit D has a switching input, which receives a switching signal indicated at half the horizontal frequency (1/2 FH) from a source, not shown, so that the outputs are alternately connected to a signal input during the periods THS1 and THS2 specified. This signal input of the switching circuit D clock pulses with a specified clock pulse frequency FCP1 are supplied. Under control of the clock pulses with the frequency FCP1, the output shift register C1 delivers the expanded color type information U (or V) to an input of a forwarding circuit designated by G during the first horizontal scanning time periods THS1. Another input of the circuit G, the output register C2 supplies the expanded color type information U ′ (or V ′) during the second, subsequent horizontal scanning time periods THS2. The content of the chromaticity information U '(or V') is, apart from a shift by one register level of the input shift register A, equal to that of the chromaticity information U (or V). The circuit G alternately supplies the information U and U '(or V and V') to an input of an amplifier circuit K, from which an output is connected to the circuit output at which the expanded information U, U '(or V, V' ) appears. The amount of expansion corresponds to half the ratio of the clock pulse frequencies FCP0 and FCP1. Half the fact comes from the signal distribution via the two output shift registers C1 and C2.

When writing and reading the shift register A, C1 and C2 become the color type information Load packages pushed on. During the horizontal Blanking period THB after the period UT2 or VT3 registers C1 and C2 are in the same position considered. Then the cargo packages alternate forwarded to the relay circuit arrangement.

From Fig. 1 it emerges that a signal sampling, expansion and repetition circuit (A, B, C, D, E, G, K) provides the information U, U 'or V, V' without repetition (U 'or V') a delay arrangement is necessary. The almost identical structure of two units (A, B1, C1) and (A, B2, C2) offers one and the same signal processing for the chromaticity information, so that an optimal equality of the two successive output signals can be obtained.

From Fig. 1 it follows that the contents of the output shift registers C1 and C2 have a shift by only one register stage of the input shift register A. In order, if desired, to ensure that the (repeated) output signal originating from register C2 occurs exactly one horizontal period later than the signal from register C1, the clock pulses in registers C1 and C2 should occur in opposite phases. In Fig. 1 this has been achieved by using the phase inversion circuit E. An alternative solution is to use a signal delay arrangement with a time delay equal to half a clock pulse period (1 / 2FCP1).

Fig. 2 shows an overview of a possible embodiment of an integrated circuit arrangement with some elements shown in Fig. 1. Elements already identified in FIG. 1 are given the same or adapted reference numerals in FIG. 2. The integrated circuit arrangement according to FIG. 2 is e.g. B. formed as a charge-coupled arrangement. In this case, three parallel n-type channels are formed in a p-type semiconductor substrate. In Fig. 2, an inner channel and two outer channels are shown, which are assigned to the registers A ', C1 and C2'. In the register A ', the first and second register levels A1 and A2 are specified. The first and last stages C1 ₁ and C1 _m are specified in the register C1. In register C2 'the first and last stages C2 ₁ and C2' _m are specified. Separate p-type regions are shown between the channels. The inner channel is separated from the two outer channels by the interrupted p-conducting regions, the interruptions to the one and the other outer channel being shifted by half a region length. The outer channels meet (at G) at the end of the inner channel shot in the substrate. Electrically insulated electrode systems are provided on the substrate with the n-conducting channels and the p-conducting regions. The registers A ', C1 and C2' are each formed with a four-phase electrode system, which is denoted by 1, 2, 3 and 4. The electrode systems can be provided in a single or multi-layer structure on and in the insulating layer. For the sake of simplicity, the electrodes are shown in succession, but they are isolated from one another, with four comb-shaped electrodes being present per system. B1 and B2 in Fig. 2 are shown partially hatched, two conductive strips are indicated. The strips B1 and B2 extend over the p-type regions and the interruptions between them. These interruptions are fed under control of the strips B1 and B2, and voltages such as the switches of the on / off circuit (B1, B2) shown in FIG. 1 are effective. The two electrode strips B1 and B2 together with the interrupted p-conducting areas form the on / off circuit (B1, B2). At the circuit input with the signal U / V an n + conductive area is shown for an input contact. On the opposite side of the integrated circuit arrangement, a first n + conductive region for connection to a supply voltage is shown. Furthermore, a second n + conductive region is shown which is separated by means of an electrode of a reset gate circuit and has a connection to a transistor which is effective with an insulated gate electrode and forms part of the amplifier circuit K. The drain electrode of the transistor (K) leads to the output at which the signal U, U 'or V, V' occurs.

The simplicity of the embodiment shown in Fig. 2 from the integrated circuit arrangement with essentially the registers A ', C1, C2', the circuit (B1, B2) and the relay circuit G leads to the same signal processing for the two color types information U and U 'or V and V', which is cheap.

It should be noted that the electrode assigned to the circuit arrangement G has its own voltage supply, as a result of which the charge packets are forwarded from only the registers C1 and C2 'during the horizontal scanning periods THS1 and THS2. Furthermore, Fig. 2 shows that the last stage C2 'of the register C2' deviates from the last stage C1 _{m of} the register C1. Characterized in that the level C2 ' _{m is} only half formed with the number of electrodes in the illustrated manner, an antiphase forwarding to the forwarding circuit G is automatically achieved, so that on the circuit arrangement E, designed as a phase inversion circuit or a delay circuit with the time delay corresponding to half a clock pulse period can be dispensed with. Due to the circuit structure, the reading is already in phase opposition at the output shift registers C1 and C2 '.

For a more detailed embodiment than that of FIG. 2, reference is made to the details in US Pat. Nos. 3,965,481 and 4,207,477.

Fig. 3 shows block schematically another Ausfüh approximate shape as in Fig. 1 in Fig. 1 already indicated elements are given the same or adapted reference numerals.

So there is the input shift register unchanged A, but there are four output shift registers UC1, UC2, VC1 and VC2 there. The four output shift registers are as the double called first (C1) and second (C2) off gear shift register with a first or second scarf tion output with a signal U, U ', U or V', V, V 'ge couples. One or the other coupling has the Forwarding circuit UG or VG and the amplifier circuit UK or UK. UB1 and UB2 are on / off circuits referred to during the horizontal blanking periods THB1 are switched on. Through VB1 and VB2 are on / off Circuits specified during horizontal blanking time periods THB2 are switched on. From the switching circuit D is the output with the specified duration THS1 directly with the register UC1, but over a phase reversing circuit VE coupled to the register VC2. The end course with the duration THS2 is immediately with the regis ter VC1 and via a phase inversion circuit UE with the Register UC2 coupled. The circuits can also be used here UE and VE by delay circuits with a time ver delay corresponding to half a clock pulse period  be set.

To explain the operation of the circuit arrangement according to FIG. 3, the following applies, with the supply of a time-division multiplex signal Y / U / V with a cycle U, Y, V, Y over two horizontal periods with the durations UT2, YT1, VT3, YT1. During the period UT2, the U-chromaticity information is written into the input shift register A in the form of charge packets while controlling the clock pulses with the frequency FCP0. During the first subsequent horizontal blanking period THB1, this information is transmitted to the output shift registers UC1 and UC2 via the circuit (UB1, UB2). According to the embodiment given in FIG. 3, the information for the register UC2 can be shifted further over or around the register UC1. During the next horizontal scanning period THS1, the register UC1 with the information U to the circuit output (U, U ', U) is read out and during the second next horizontal scanning period THS2 the register UC2 with the information U' is read out. The same information processing occurs shifted by a horizontal period at the output shift registers VC1 (information V, time period THS2) and VC2 (information V ′, time period THS1) after these have been filled out of register A during the horizontal blanking period THB2 after the information period VT3 are. Fig. 3 shows that with a signal sequence U, U ', U at one circuit output, the other circuit output leads the signal sequence V', V, V '.

In Fig. 4, an embodiment of an integrated circuit arrangement is shown, which can be effective according to the circuit arrangement of FIG. 3. For a description of the area structure of the circuit arrangement according to FIG. 4, reference is made to the description of FIG. 2. Fig. 4 shows five parallel channels of the n-semiconductor type. The inner channel (A ') is separated from the two adjacent channels (UC1, VC1) by the interrupted p-conductive regions. The interruptions are opposite each other. The adjacent channel (UC1, VC1) is separated by further interrupted p-conducting regions from an outer channel (UC2 'or VC2'), the number of further interruptions being half the number on the other side. The outer channel (UC2 'or VC2') and the adjacent channel (UC1 or VC1) meet at one end. In Fig. 4, five separate, from the sub strate isolated electrode systems are available over the channels in question. On both sides of the adjacent channels (UC1 and VC1) there are electrode strips UB1 and UB2 or VB1 and VB2 above the conductive areas, which together with the p-areas one of the on / off switching circuits (UB1, UB2) and (VB1, VB2 ) assigned. The registers UC1 plus UC2 'and VC1 plus VC2' are alternately filled with information from register A '. According to FIG. 4, the information for the register UC2 is 'and VC2' (, VB2 VB1) pushed by means of the on / off circuit (UB1, UB2) or by the register UC1 and VC1. For a more detailed version, reference is made to US Pat. No. 4,131,950.

Another embodiment is shown in FIG. 5 than in FIG. 1. Elements already identified in FIG. 1 are given the same or adapted reference numerals. Instead of the single input shift register A in FIG. 1, there are first and second input shift registers A1 and A2 according to FIG. 5. The input and output shift registers A1, A2 and C1, C2 are all designed with a number of m register stages. In the manner described in FIG. 1 for the units (A, B1, C1) and (A, B2, C2), the unit (A1, B1, C1) supplies the information U (or V) and the unit (A2 , B2, C2) the information U ′ (or V ′).

The supply of the relevant color type information to registers A1 and A2 is done via a single Ab key circuit A0 and a switching circuit L. The circuit A0 become sampling clock pulses with the clock pulse frequency FCP0 fed. The clock pulses with the frequency FGP0 are using a frequency divider Q with a division factor two (F: 2) one switching input of the switching circuit L  fed. The clock pulses with the frequency 1/2 FCP0 continue to be immediately a clock pulse input of the Input shift register A1 fed and are via a Phase inversion circuit R a clock pulse input of the on gear shift register A2 supplied. Instead of the phases reversing circuit R can have a delay arrangement a time delay corresponding to a clock pulse period 1 / FCP0 can be used.

In the case of color type information transport during the period UT2 or VT3, this information is written in distributed over the two input shift registers A1 and A2 in the form of load packets. The registers A1 and A2, which are active in terms of phase, are operated by the clock pulses at the frequency 1/2 FCP0, which can be advantageous against the double clock pulse frequency FCP0 with the single input shift register A from FIG. 1. The extent of the signal expansion corresponds to a factor of 1/2 FCP0 divided by FCP1. As the circuit arrangement of FIG. 3 shows a possible extension of the TIC arrangement of Figure 1., Can be the same Extension C 5 tion provided in the circuit arrangement of FIG..

Instead of using the switching circuit L for the distribution of information can be a common one level at registers A1 and A2, in which the color type information available as a charge package is divided into two equal cargo packages, then synchronized, who is pushed through registers A1 and A2 the.

A circuit arrangement according to the Fig. 5 pas send integrated circuit can be realized in that the input shift register A 'into two is divided from each separate input shift register in the given in Fig. 2 embodiment in a simple manner. One can think of providing a closed p-type region in the middle, in the longitudinal direction of the inner n-type channel. The same change can be provided in the integrated circuit given in FIG. 4 , so that the expansion given in FIG. 3 can also be carried out in FIG. 5. For all forms of execution of the integrated circuit applies that in the p-type circuit substrate at least three parallel n-type channels are present, wherein an inner channel is separated from an adjacent outer channel by interrupted p-type regions. Insulated from the substrate there are separate electrode systems above the channels, which are assigned to the input shift registers A ', A1 and A2 or the output shift registers C1 and C2, UC1 and UC2' or, VC1 and VC2 '. Above the areas mentioned and insulated from them there is the electrode strip which, together with the areas, is assigned to the on / off circuit (B1, B2), (UB1, UB2) or (VB1, VB2).

Claims (10)

1. Color television receiver with a television circuit for converting a time-division multiplex signal into simultaneous signals, this time-division multiplex signal having an interrupted sequence of first information relating to the luminance, occurring in first time periods, the first information being replaced by another sequence of second and third information with respect to the type of color, occurring in second and third periods of time, are separated and the simultaneous signals correspond to the first information, the second and third information and repeated third and second information, the possibly repeated second and third information tions second are expanded, whereby they appear in the same simultaneous signals during the same first and fourth periods as the first information, the periods corresponding to television horizontal scanning periods, for which purpose the television circuit between a circuit input and output with signal sampling, -ex pansions- and repetition circuits for the second and third information is formed in relation to the color type, the circuits with shift registers with different write or read speeds under control of clock pulses with different clock pulse frequencies are formed, characterized in that in the Signalabtast-, -expansions- and -wiederholungs circuit the input of the television circuit with a signal input of at least one input shift register (A, A1 or A2) of the type series-in, parallel-out is coupled and the relevant output of the television circuit with the expanded, possibly repeated second or third information relating to the type of color is coupled to the relevant signal outputs of a first and second output shift register (C1, C2 or UC1, UC2 or VC1, VC2) of the type parallel-in, row-out , with parallel outputs of the input shift register via an on / off circuit (B1, B2 or UB1, UB2 or VB1, VB2) are coupled to parallel inputs of the first or second output shift register, the on / off circuit being switched on periodically before the first or fourth time periods occur, during television horizontal blanking time periods, and is turned off during the first and fourth periods corresponding to the television horizontal scanning periods, alternately the first and second output shift registers per relevant horizontal scanning period, the second and third information and the repeated second and third information on the delivers relevant circuit output. 2. Color television receiver according to claim 1, characterized ge indicates that the signal sampling, expansion and -Repeat circuit with a single input swipe register (A) with a number of register levels that more or less twice the number of register stages of the off gear shift register (C1, C2 or UC1, UC2 or VC1, VC2) corresponds, is formed, the parallel outputs of the input shift register one after the other alternately with the parallel inputs of the first and second output shift registers are coupled. 3. Color television receiver according to claim 1, characterized characterized in that the signal sampling, expansion and -Repeat circuit with a first and a second Input shift register (A1 or A2), each with a number Register levels that are more or less the number of registers stages of the output shift register (C1 or C2), is formed, the parallel outputs of the first or second input shift register with the parallel gears of the first and second output shift register are coupled. 4. Color television receiver according to claim 3, characterized in that the clock pulse frequency at the sampling circuit (A ₀ ), the output of which is coupled via a switching circuit (L) to the relevant signal input of the first and second input shift registers (A1 and A2), twice larger is the clock pulse frequency for these input shift registers and the switching circuit. 5. Color television receiver according to one of the preceding Claims, characterized in that the reading when first and second output shift registers (C1, C2 and C1, C2 ′) is in phase opposition. 6. Color television receiver according to one of the preceding Claims, characterized in that the signal sampling, -Expansion and repeat circuit with four off gear shift registers (UC1, UC2, VC1, VC2) is formed, which than twice said first and second output shift registers (C1, C2) with a first or second Output of the television circuit are coupled, the On / off circuits (UB1, UB2 or VB1, VB2) the one or other pair of first and second output slides registers (UC1, UC2 or VC1, VC2) are assigned to change as during the first and second horizontal blanking time last are effective. 7. Color television receiver according to one of the preceding claims with an integrated circuit arrangement, characterized in that in a circuit substrate of a first semiconductor type at least three parallel channels (A ', C1, C2' or A ', UC1, UC2' or A ', VC1 , VC2 ′) of another semiconductor type are present, an inner channel being separated from an adjacent outer channel by interrupted regions of the first semiconductor type, separate electrode systems being present isolated from the substrate above the channels which are assigned to the input or output shift register, an electrode strip ( 31 , 32 or UB1, UB2 or VB1, VB2) being present in the substrate and insulated therefrom, said strip and the areas being assigned to the on / off circuit. 8. Color television receiver according to claim 7 Connection with claims 1 or 2, characterized in that that in  the circuit substrate of the first semiconductor type three parallel channels (A ′, C1, C2) of the other semiconductor type are present, with the inner channel (A ') through under broken areas of the first semiconductor type of the two outer channels (C1, C2) is separated, these Interruptions half a length of area to one and other outer channel are shifted, the outer channels on a closed in the substrate Meet the end of the inner channel (G), being isolated from the substrate three separate electrode systems above the inner channel and the two outer channels that make up the input shift register or the two initial catch registers are assigned, being on both sides of the inner channel over the areas mentioned in the Substrate and isolated from it, two electrode strips (B1, B2) which together with the areas the on / off circuit are assigned, exist. 9. Color television receiver according to claim 7 in connection with Claim 6 with reference to claim 1 or 2, characterized characterized in that in the circuit substrate of the first Semiconductor type five parallel channels (A ′, UC1, VC1, UC2 ′, VC2 ′) of the other semiconductor type are present, the inner channel (A ′) through interrupted areas of the first Semiconductor types from the two adjacent channels (UC1, VC1) is separated, with the interruptions facing each other one another, with a neighboring channel called through broken areas of the first semiconductor type of one outer channel (UC2 'or VC2') is separated, the Interruptions between the outer and the adjacent channel with half the number of breaks between the inner channel and the adjacent channel are present and where an outer channel and the adjacent channel at one end too meeting (G), being isolated from the substrate five separate electrode systems over the inner channel and the two adjacent channels and two outer channels, the the input shift register or the four output shifts registers are assigned, exist on both  Pages of the neighboring channels over the areas mentioned in two electrode strips are insulated from the substrate and from it (UB1, UB2 or VB1, VB2) are available together with the areas assigned to one of the on / off circuits are. 10. Color television receiver according to claim 8 or 9 in conjunction with claim 5, characterized in that the coinciding channels at this point have a last output shift register stage (G), the number of electrodes of a last stage (2 ' _m ) half from the other last stage (C1 _m .